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Pair Distribution Function Analysis of Structural Disorder by Nb Inclusion in Ceria: Evidence for Enhanced Oxygen Storage Capacity from Under-Coordinated Oxide 5+
Craig Hiley, Helen Y Playford, Janet Fisher, Noelia Cortes Felix, David Thompsett, Reza J. Kashtiban, and Richard I. Walton J. Am. Chem. Soc., Just Accepted Manuscript • DOI: 10.1021/jacs.7b12421 • Publication Date (Web): 19 Jan 2018 Downloaded from http://pubs.acs.org on January 19, 2018
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Journal of the American Chemical Society
Pair Distribution Function Analysis of Structural Disorder by Nb5+ Inclusion in Ceria: Evidence for Enhanced Oxygen Storage Capacity from Under-Coordinated Oxide Craig I. Hiley,† Helen Y. Playford,‡ Janet M. Fisher,§ Noelia Cortes Felix,§ David Thompsett,§ Reza J. Kashtiban,ǁ Richard I. Walton†* †
Department of Chemistry, University of Warwick, Coventry, CV4 7AL UK, ‡STFC ISIS Facility, Rutherford Appleton Laboratory, Oxfordshire, OX11 0QX, UK, §Johnson Matthey Technology Centre, Sonning Common, Reading, RG4 9NH, UK, ǁ Department of Physics, University of Warwick, Gibbet Hill Road, Coventry, CV4 7AL UK.
Supporting Information Placeholder ABSTRACT: Partial substitution of Ce4+ by Nb5+ is possible in CeO2 by co-inclusion of Na+ to balance the charge, via hydrothermal synthesis in sodium hydroxide solution. Pair distribution function analysis using reverse Monte Carlo refinement reveals that the small pentavalent substituent resides in irregular coordination positions in an average fluorite lattice, displaced away from the ideal cubic coordination towards four oxygens. This results in under-coordinated oxygen, which explains significantly enhanced oxygen storage capacity of the materials of relevance to redox catalysis used in energy and environmental applications.
Cerium dioxide, or ceria, has numerous applications in heterogeneous catalysis. The reversible reducibility of Ce4+ ions and high mobility of oxide ions in the solid-state1 give rise to significant oxygen storage properties that make the material an ideal redoxactive support for a wide range of catalytic processes such as in automotive emission control,1b low temperature water-gas shift catalysis for hydrogen purification2 and in selective oxidation catalysis for conversion of organics,3 as well as an oxideconducting solid-electrolyte.4 The current focus on ceria-based materials is aimed at further improvement of oxygen storage capacity for new and emerging energy and environmental applications5 and there is a continued need for new synthetic routes to ceria materials with favorable oxygen storage properties. Inclusion of substituent metals can produce drastic improvements in the redox properties of ceria by introducing strain, increasing the oxide vacancy concentration and/or improving high temperature stability.6 Many transition-metal cations have been reported as substituents into ceria,7 and often these are considerably smaller than Ce4+ and have a strong preference for octahedral geometry. In this communication we consider the preparation of substituted ceria by a low-temperature hydrothermal route8 where the inclusion of the pentavalent niobium leads to thermally robust materials with oxygen storage capacities much greater than pure ceria. The choice of a pentavalent substituent ion is counterintuitive, since its presence alone would imply the need for oxygen excess for charge balance, but we show how Na+ as co-substituent provides a mechanism for charge balance. Previous work on niobium-containing ceria is limited, compared to the extensive stud-
ies made of other substituent cations, but includes materials for catalysis, with rather small amounts of Nb present (typically 5 atom %)9 or in fact as phase separated oxides,10 but no structural study has been performed. We use reverse Monte Carlo (RMC) analysis of neutron total scattering data to obtain atomistic structural models for the materials and compare them with unsubstituted ceria: this reveals new information about the extent of oxideion disorder in this important class of materials that shows how local structure may be dramatically disrupted by inclusion of substituent cations, despite retaining an average cubic fluorite structure. Materials were prepared by the hydrothermal reaction of (1−x)CeCl3·7H2O, xNbCl5 and H2O2 in NaOH solution at 240 °C (see Supporting Information for full details). For samples with x ≤ 0.30 all powder XRD peaks from the materials can be indexed to a face-centered fluorite unit cell (Figure S1). When x = 0 the refined cell parameter a is 5.415(1) Å, close to the NISTdetermined value for highly crystalline CeO2 (5.411651(1) Å).11 As x increases, a linear decrease in a is observed to 5.3669(6) Å for x = 0.30 (Figure 1a), explained by the inclusion of the smaller Nb into the fluorite lattice. Further to this, the F2g phonon mode in the Raman spectra, associated with eight-coordinate M–O bond vibrations, displays a slight shift to lower wavenumber with increasing x, from 464 cm-1 to 459 cm-1, consistent with shorter M– O bonds (Figure 1b);12 although the effect of decreasing crystal domain size, as observed by Scherrer analysis of powder XRD patterns (Figure 1a) and by HR-TEM (Figure 1d-f)), may also contribute.13 The intensity of Raman peaks at 540 cm-1 and 600 cm-1 (labelled α and β, respectively), attributed to second-order phonon modes caused by oxide vacancies/defects,12-14 increase as a function of x. Ce LIII- and Nb K-edge X-ray absorption nearedge structure (XANES) spectra (Figures S3 and S4) give no indication for reduction of the metals from their highest oxidation-states (+4 and +5 for Ce and Nb, respectively). Instead, charge balance in these materials was found to be achieved by adventitious co-substitution of Na from the hydrothermal reaction mixture, to give general formula (Ce1-xNbx)1-yNayO2-δ (where x ≤ 0.30 and y ≥ ~x/3). Elemental analysis by ICP-OES shows that the amounts of Na and Nb increase such that the proportion of Na, y, is always at least a third of the Nb content (~x) (Figure 1c), the minimum level of Na substitution required to achieve charge bal-
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ance. The excess Na substituted into the structure allows oxide vacancies, and Na incorporation into complex cerium oxides has been previously shown to generate oxide-deficient fluorite type materials with notably high low-temperature reducibility.15
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shows a drastic expansion as the Ce4+ is again reduced, demonstrating the cyclability of the reduction. Oxygen storage capacity (OSC) measurements were carried out to assess further the kinetically available oxygen in the materials, which is of direct applicability to their use as oxygen buffers in catalytic systems. Alternating pulses of CO and O2 were passed over a sample (loaded with 0.5 wt% Rh, see Experimental Section) and the breakthrough time (the time taken for CO to be detected in the gas stream after passing over the sample), t, (Figures 2d, S6) of CO was used to calculate the OSC at a given temperature (Figure S7). These data, normalized to surface area to account for morphological effects, demonstrate that OSC per unit area is greatly improved by Nb incorporation (Figure 2e). The coordination environment of Nb within the fluorite lattice so far remains unclear. Rietveld models in space group ��3�� with a mixed metal 4a site fail to provide satisfactory agreement with neutron powder diffraction data collected from samples x = 0.10, 0.20, 0.30 (Figures S8-11, Table S3). Neutron total scattering data were therefore collected from samples with a nominal composition x = 0.20 (both as-made and fired at 500 °C for 5 hours) along with highly crystalline CeO2 (NIST) and hydrother-
Figure 1. (a) Refined lattice parameter (black) and Scherrer crystallite size (red) from powder XRD of (Ce1-xNbx)1-yNayO2-δ as a function of Nb content, x, with lines of best fit. Error bars smaller than data points. (b) Raman spectra with a 514 nm excitation laser. (c) ICP-OES measured Nb and Na content as a percentage of total metal content (remainder Ce). (d-f) HR-TEM micrographs with nominal values of x of 0, 0.10 and 0.20, respectively. All micrographs are presented at the same scale for comparison. The reducibility of the materials was initially assessed by H2 temperature-programmed reduction (TPR, Figure 2a), showing that samples exhibit two H2 uptakes – one at low temperature (
